A pyroxene‐bearing meta‐ironstone and other pyroxene‐granulites from Tonagh Island, Enderby Land, Antarctica: further evidence for very high temperature (> 980°C) Archaean regional metamorphism in the Napier Complex

A suite of granulites including a meta‐ironstone, pyroxenites, and spinel‐lherzolites from East Tonagh Island, Enderby Land, Antarctica, preserve exsolution‐recry‐stallization features consistent with a shared metamorphic evolution that involves marked cooling from initial metamorphic temperatures of nearly 1000°C. Reintegrated pre‐exsolution and pre‐reaction grain compositions in the meta‐ironstone indicate the former coexistence of metamorphic pigeonite (Wo 12 En 38 Fs 50 ) and ferroaugite (Wo 35 En 31 Fs 34 ) at temperatures in excess of 980°C for pressures of 7 kbar (0.7 GPa) using pyroxene quadrilateral thermometry (Lindsley, 1983). Intra‐grain lamellae relationships indicate the exsolution of a second pigeonite (Wo 12 En 35 Fs 53 ) from the ferroaugite at temperatures in the range 930–970°C, prior to the c. 720–600°C exsolution of orthopyroxene and clinopyroxene (100) lamellae and later partial recrystallization at similar temperatures. Although pyroxenitic and iherzolitic granulites preserve a much less complete history, reintegrated porphyroclast compositions in these yield temperature estimates which approach those inferred from the metaironstone. Pyroxene thermometry based on neoblast compositions suggests that recrystallization post‐dating a late, low intensity, deformation phase (D3) occurred at temperatures greater than 600°C. These results are consistent with the independent evidence obtained from studies of metapelitic and felsic rock types for very high temperature metamorphism throughout the Napier Complex followed by near‐isobaric cooling and later deformation under lower‐grade granulite facies conditions. Comparison with similar pyroxene data from Fyfe Hills (Sandiford & Powell, 1986) demonstrates further the regional significance of these high temperatures, and implies broadly isothermal metamorphic conditions over a large area (∼ 5000 km 2 ) and thickness (6–9 km) of lower crust at c. 3070 Ma.